DE102010018945A1 - Apparatus for producing a spray jet containing solids - Google Patents

Abstract

The present invention relates to a device for producing a filler-containing spray jet for producing layers and / or molded parts from a reactive resin in the shot mode. The fillers are evenly wetted with the resin in a device according to the invention.

Description

The present invention relates to a device for producing a filler-containing spray jet for producing layers and / or moldings from a reactive resin in the weft operation.

The use of different reactive resins for the production of moldings is well known in the art. When it comes to applying a reactive resin to a substrate, spraying has usually prevailed as a coating technique. As reactive resins, polyurethanes are often used. In addition, however, other two- or multi-component systems such as epoxy resins or (meth) acrylic-based resins are also used.

Usually, the mixing of the liquid reactive components takes place in a mixing head, wherein basically between high pressure (HD) and low pressure (LP) mixture can be distinguished. In the low-pressure process, the components are mixed in a pressure range up to 40 bar. By synchronously opening valves, the reactive components are released in the desired ratio in the mixing chamber. In this mixing then takes place by stirring, for example with an intensive mixer, or static mixer instead.

In high-pressure machines, the reactive components circulate in a pressure range up to 250 bar. Upon initiation of a shot, the individual reactive components meet with the corresponding high pressure in the mixing chamber and thereby mix.

The spray application is realized both in the HD and in the ND process via downstream atomizer systems.

For many applications it is necessary to add additional components to the reactive resin. Depending on the end product, this could be fire retardants, aging inhibitors or UV protectants, which impart the required properties to the molded part or the layer of the reactive resin. Furthermore, it is also possible to mix fibers which increase the stability of the product obtained. The admixture of solid, liquid and / or gaseous components in the reactive mixture has been realized in different ways in the prior art. Frequently, the additives are dispersed or dissolved in one of the reactive components used for the resin. One possibility is to mix the additives to be used with one of the two reactive components and to use the mixture thus obtained to prepare the resin.

In DE 39 09 017 C1 and DE 40 10 752 A1 For example, the production of expanded graphite or expandable graphite / melamine-containing flexible polyurethane foams is described. The additives used herein are dispersed in the polyol component of the polyurethane. The problem here is that the additives are not soluble in the corresponding component. The dispersion must therefore be stirred constantly to avoid sedimentation of the solid in the reservoir. In the case of melamine in a Polyoldispersion also shows that after sedimentation, the melamine cakes quickly, which makes redispersing much harder, sometimes even impossible.

When additives are dispersed in the polyol component of the polyurethane, components from the polyol formulation can adsorb to the surface of the added solids.

In the sedimentation of solids, these components are finally removed from the polyol formulation. In particular, if the redispersion of the sediment is difficult, this leads to deviations in the polyol composition and thus to new properties of the polyurethane resin to be produced. For example, the curing time of the resin is changed thereby.

Even solids with different specific gravity (based on the carrier liquid) can be processed so poorly. Hollow glass spheres may, for example, float in the reactive component, swelling in the case of wood flour.

In addition, if necessary, the physical properties, for example the viscosity, of the corresponding liquid reactive component are also changed by the presence of an additive, as a result of which the miscibility of the reactive components is usually adversely affected. In addition, when processing solid additives in the corresponding liquid reactive components via HD or LP equipment, shear forces act on the additives. As a result, they are crushed, which can change their effect in the resin uncontrolled. Sometimes chemical side reactions of the additives with the reactive components can not be excluded.

An alternative to the production of filler-containing layers or moldings from a reactive resin is the injection process, in which a filler-containing gas stream is passed into a stream of the reactive components.

The mixing of reactive components with a filler component can be done outside the mixing head. This is for example DE 25 17 864 A1 . US-A-3,302,891 . WO 2009/052990 A1 or EP 1 458 494 B1 known. Here, the mixing of a spray of reactive plastic with a spray of the corresponding filler takes place. In the context of the present invention, a spray jet is also understood to mean a jet which consists essentially of fine particles (droplets) of a reactive mixture dispersed in a gas stream, ie a mixture of at least two reactive components.

If fillers and reactive mixture are mixed downstream of the mixing chamber, the wetting of the filler with the resin is often incomplete.

Out WO 2009/143979 A1 a method is known in which the gas stream containing solids is not introduced into the already dispersed spray jet of the reaction mixture, but into the still liquid non-dispersed jet of the reaction mixture. About a mixing head downstream header with an integrated mixing level, the gas solid mixture is fed to the liquid non-dispersed reaction mixture, mixed by means of the resulting Rotationsdralls and then discharged as a multi-phase mixture via a nebulizer as a spray. When processing higher solids contents, however, the wetting of the particles may also be incomplete here. High solids contents with small particle sizes provide the reaction mixture with a large surface area which, due to the short residence time in the mixing zone, can not be sufficiently mixed and wetted with the reaction mixture. In addition, solid particles of high specific gravity concentrate on the wall region of the flow channel due to centrifugal forces and can only be mixed to a limited extent with the reaction mixture due to the compression.

DE 10 2007 016 785 A1 relates to a method and an apparatus for producing molded parts, comprising a layer of polyurethane in the weft operation, in which a gas stream is introduced into the flow channel of the spraying device at at least two positions. DE 44 17 596 A1 describes a method of making a blend of reactive plastic components and fillers. Here, the plastic components are mixed under high pressure in a mixing chamber and get out of this as a plastic component mixture in a arranged at an angle to the mixing chamber outlet pipe, in which the fillers are registered and wetted intensively with the plastic component mixture. The inlet opening for the solid in the flow channel faces the inlet opening for the plastic mixture. Here, however, only fine-grained and free-flowing solids can be processed, which do not tend to clump.

EP 0 771 259 B1 comprises an apparatus for producing plastic parts interspersed with long reinforcing fibers. Here a wetting of the solid and liquid components takes place at the discharge itself, but it is not a spray.

The object of the present invention is therefore to provide a device for the production of layers and / or moldings from a reactive resin in the weft operation, with which different fillers in a high proportion based on the amount of reactive resin in both high pressure (HD) - and in the Low pressure (ND) method can be sprayed processed. In this case, a uniform wetting of the filler (s) and also a homogeneous distribution of the filler (s) in the final product must be ensured. Another object of the present invention is that the self-cleaning of a flow channel containing at least filler and transport gas is ensured.

• a. einen zylindrischen Füllstoffkanal 6 mit wenigstens einem Einlass 1 zur Einleitung eines Gemisches aus Transportgas und Füllstoff und einen darin befindlichen axial beweglichen Ausstoßer 8,
• b. einen zylindrischen Strömungskanal 9 zur Einleitung von Füllstoff aus dem Füllstoffkanal 6 und
• c. eine zylindrische Mischkammer 5 mit wenigstens zwei Einlassöffnungen 4 für die Zudosierung von wenigstens zwei Reaktivkomponenten umfasst,

wobei die Mischkammer 5 und der Füllstoffkanal 6 einen Winkel einschließen, der ungleich 180° ist, während der Füllstoffkanal 6 und der Strömungskanal 9 einen Winkel von 180° einschließen.The object underlying the present invention is achieved by a device for producing a filler-containing resin spray, which is characterized in that they

• a. a cylindrical filler channel 6 with at least one inlet 1 for introducing a mixture of transport gas and filler and an axially movable ejector located therein 8th .
• b. a cylindrical flow channel 9 for introducing filler from the filler channel 6 and
• c. a cylindrical mixing chamber 5 with at least two inlet openings 4 for the metered addition of at least two reactive components,

the mixing chamber 5 and the filler channel 6 include an angle that is not equal to 180 ° while the filler channel 6 and the flow channel 9 enclose an angle of 180 °.

According to the invention, it may be in the mixing chamber 5 to act an HD or ND mixing chamber, such as a static mixer. Is it the mixing chamber 5 around an HD mixing chamber, so the device according to the invention further comprises an ejector 2 for mechanical cleaning of the mixing chamber 5 on. A corresponding device shows schematically 1 ,

• a. wenigstens ein Füllstoff und wenigstens ein Transportgas über wenigstens einen Einlass 1 in den Füllstoffkanal 6 geleitet werden und die Füllstoff-Gas-Mischung aus dem Füllstoffkanal 6 in den Strömungskanal 9 geleitet wird,
• b. in der Mischkammer 5 über wenigstens zwei Einlassöffnungen 4 wenigstens zwei Reaktivkomponenten im Hochdruck oder Niederdruck eingebracht und miteinander vermischt werden und das so erzeugte Reaktivgemisch in den Strom aus Füllstoff-Gas-Mischung im Strömungskanal 9 eingeleitet wird,
• c. das resultierende, dann Füllstoff enthaltende Reaktiv-Gas-Gemisch über eine Austrittsöffnung 7 den Strömungskanal 9 verlässt,
• d. anschließend die Mischkammer 5 gereinigt wird und
• e. der Füllstoffkanal 6 und der Strömungskanal 9 mittels des Ausstoßers 8 mechanisch gereinigt werden, in dem dieser in seine Reinigungsposition, in welcher der Ausstoßer 8 in den Strömungskanal 9 geführt wird, bewegt wird.

A device according to the invention makes it possible to carry out a process for producing a corresponding filler-containing resin spray jet, in which

• a. at least one filler and at least one transport gas via at least one inlet 1 in the filler channel 6 be passed and the filler-gas mixture from the filler channel 6 in the flow channel 9 is directed
• b. in the mixing chamber 5 over at least two inlet openings 4 at least two reactive components are introduced in high pressure or low pressure and mixed together and the reactive mixture thus produced in the flow of filler-gas mixture in the flow channel 9 is initiated
• c. the resulting, then filler-containing reactive gas mixture via an outlet opening 7 the flow channel 9 leaves,
• d. then the mixing chamber 5 is cleaned and
• e. the filler channel 6 and the flow channel 9 by means of the ejector 8th be mechanically cleaned, in which this in its cleaning position, in which the ejector 8th in the flow channel 9 is guided, is moved.

In the HD method, step d of the method further comprises the mechanical cleaning of the mixing chamber 5 by means of the ejector 2 ,

In the HD method, the ejector is successively cleaned to clean the device according to the invention 2 and the ejector 8th moved from the firing position in its cleaning position. The firing position means that the ejector 2 in the sense of the flow direction in front of the at least two inlet openings 4 so that these and the mixing chamber 5 from the ejector 2 not be obscured. The ejector 8th is in the firing position in the direction of the flow direction in front of the at least one inlet 1 , In mixing chamber 5 , Flow channel 9 and filler channel 6 can thus take place a transport and mixing of the components. The mixture is free to the outlet opening 7 reach and the reactive resin-filler mixture are discharged in the shot mode.

At the end of the shot, the ejector will be in the HD process 2 and the ejector 8th one after the other moved into cleaning position. This will be the mixing chamber 5 , Filler channel 6 and flow channel 9 mechanically cleaned, with the mixing chamber 5 through the ejector 2 and filler channel 6 and flow channel 9 through the ejector 8th getting cleaned.

In the ND process, the mixing chamber 5 cleaned in a conventional manner by a liquid detergent and / or compressed air. The filler channel 6 and the flow channel 9 are also used in the ND procedure by the ejector 8th cleaned as previously described in the HD method. Moving the ejector 8th in its cleaning position after the mixing chamber 5 was cleaned.

While the prior art devices essentially use a gas stream or nozzle to atomize a reactive mixture and inject a further gas stream containing such solids into such atomized spray, the device of the present invention is characterized by having a solids-containing gas stream through a filler channel 6 in a flow channel 9 is initiated. In the transition area between filler channel 6 and flow channel 9 gets out of the mixing chamber 5 the reactive mixture introduced into this stream of filler and transport gas. This results in a mixing of at least one filler with the reactive mixture, whereby this (r) is wetted by the reactive mixture / are.

A reactive mixture is understood according to the invention to mean a mixture of at least two, in particular liquid, reactive components which are mixed with one another in the region of a mixing chamber in the HD or LP process. Such a reactive mixture is not in the form of finely dispersed reaction droplets, but is a liquid viscous jet.

According to the invention, with the aid of at least one transport gas, one or more fillers in the filler channel 6 transported. A filler is understood as meaning those substances which impart desired properties, such as mechanical stability or resistance to UV radiation, to the reactive resin layers or moldings to be produced. Corresponding fillers are well described in the prior art. The fillers may be used singly or in combination. According to the invention, the fillers may have the same or different physical properties, such as density, and / or the same or different geometric configuration. If a filler-containing reactive mixture is described below, this includes reactive mixtures which contain one or more fillers.

If the stream of reactive mixture and the filler-gas mixture meet, turbulences occur within the flow channel due to the different directions of flow 9 and thus to a thorough mixing of the filler (s) with the reactive mixture. In a device according to the invention, it is therefore also possible to process particularly high filler contents of up to 83% by weight, based on the composite. Thus, it is possible to process 100 g of filler, for example in the form of BaSO ₄ , with 20 g of reactive mixture.

1 schematically shows a device according to the invention. 2a and 2 B show an alternative embodiment.

In a device according to the invention, over the at least two inlet openings 4 at least two reactive components in the mixing chamber 5 in which the reactive mixture is formed from the corresponding reactive components introduced. The reactive mixture is a reactive resin, for example a polyurethane, polyester or epoxy resin, in particular it is a polyurethane resin. If polyurethane resins and polyurethane reactive mixtures are described below, this also applies as a synonym for polyester and epoxy resin.

To produce a polyurethane reactive mixture, the at least two inlet openings are used 4 at least one polyol as a reactive component and at least one isocyanate as further reactive component in the mixing chamber 5 initiated. In this case, it is possible to use any polyols and isocyanates known from the prior art with which polyurethanes can be prepared. According to the invention, it is also possible different polyol and isocyanate components on the same or different inlet openings 4 into the mixing chamber 5 contribute.

The reactive components of any reactive resin are HD or ND-process in the mixing chamber 5 brought in. Here is a thorough mixing of the individual reactive components. The reactive mixture thus produced is in the flow of the filler-gas mixture in the flow channel 9 initiated.

About the filler channel 6 is a filler-gas mixture in the flow channel 9 directed. In accordance with the invention, filler channel 6 and flow channel 9 an angle of 180 °. This allows the use of different types of fillers. For example, fibrous, platelet or spherical fillers can be processed and also those with a high abrasive effect. The filler (s) may, for example, have a particle size of up to 2 mm, preferably up to 1 mm, in particular preferably up to 600 μm. They can be used singly or in combination with the transport gas in the filler channel 6 be initiated.

According to the invention, the filler is preferably fibers, for example glass fibers or mineral fibers, in particular wollastonite, through which the resulting product has improved mechanical stability. Further, as the filler, a flame retardant material may be used, such as expanded graphite, melamine or aluminum hydroxide. Fillers that have a high specific mass, such as BaSO ₄ or magnetite, improve the acoustic properties. Defoaming can be achieved by the addition of molecular sieves for water, for example Baylith ^® powder. For an improved surface quality is the use of particularly fine-grained fillers, such as finely ground chalk. Other fire protection agents, UV protection agents or aging protection agents which are well known from the prior art can also be introduced into the reactive mixture in a process according to the invention.

As the transport gas for the / the filler (s) is inert gas, air, nitrogen and / or carbon dioxide use. In particular, air is used as a transport gas. In order to ensure a sufficient transport of the / the fillers (s), the transport gas flows with a volume flow up to 700 nl / min, in particular with a volume flow up to 500 nl / min in the filler channel 6 one.

The degree of loading of the transport gas, defined as the mass of filler in kilograms per kilogram of transport gas, can be up to 30 kg of filler per 1 kg of transport gas, preferably up to 15 kg of filler per 1 kg of transport gas, more preferably up to 12 kg of filler per 1 kg of transport gas ,

In one possible embodiment, the device according to the invention also has at least one gas channel 3 , prefers several gas channels 3 , on, in at least one plane in the flow channel 9 lead. About this at least one gas channel 3 is a mixed gas in the flow channel 9 brought in. In the flow channel 9 meet filler reactive mixture and mixed gas on each other. Due to their different flow directions, a further thorough mixing of the reactive mixture with the filler takes place.

In a device according to the invention, the at least one gas channel 3 be arranged so that the flow direction of the gas flow of the mixed gas upon entry into the flow channel 9 outside the center of the flow channel 9 runs. As a result, a radial flow in one direction (rotation direction) is impressed on the axial flow of the filler-containing reactive gas mixture. Are several gas channels 3 exist at different levels and they are arranged so that the flow direction of the gas flow of the mixed gas at the entrance to the flow channel 9 outside the center of the flow channel 9 extends, this radial flow component preferably in a plane in a rotational direction and in the following plane in the opposite direction of rotation.

Such a tangential arrangement of the at least one gas channel 3 leads to a turbulence of the filler-containing reactive mixture, whereby a homogeneous wetting of the filler (s) is ensured with the reactive mixture.

In addition to such a tangential arrangement, it is also possible according to the invention the at least one gas channel 3 to arrange axially in one plane. Here, the flow direction of the gas flow of the mixed gas passes when entering the flow channel 9 in the middle of the flow channel 9 ,

According to the invention, it is possible for both a tangential and in an axial arrangement, that several gas channels 3 are at different levels. Are at least two gas channels 3 on one level, they can face each other on the level. The mixed gas can then be in the flow channel 9 over the at least two gas channels lying on the same plane 3 be introduced, that the flow direction of the flow of the mixed gas when entering the flow channel 9 in the middle of the flow channel 9 runs. However, according to the invention it is also possible that the inlet openings of the at least two gas channels lying on the same plane 3 in the flow channel 9 not opposed to each other. The mixed gas can then be in the flow channel 9 over the at least two gas channels lying on the same plane 3 be introduced, that the flow direction of the flow of the mixed gas when entering the flow channel 9 outside the center of the flow channel 9 runs.

According to the invention, the at least one gas channel 3 and the flow channel 9 an angle in the range of 0 to 180 °. Depending on the type and amount of filler (s) used / used, the choice of the angle can be used to optimize the mixing between the filler and the reactive mixture.

About the at least one gas channel 3 can a mixed gas in the flow channel 9 be initiated. Inertgas, air, nitrogen and / or carbon dioxide are used as mixed gas, in particular air is used as mixed gas.

In a device according to the invention, the mixing chamber 5 and the filler channel 6 and the flow channel 9 after firing in the case of the HD method by the ejector 2 and the ejector 8th or in the ND procedure by the ejector 8th cleaned. During the mixing of the reactive components with each other or the mixing of the reactive mixture with the solid-gas mixture are the ejector 2 and the ejector 8th in firing position.

At the end of the shot, the ejector is in the HD process 2 moved to cleaning position. This will cause the mixing chamber 5 mechanically cleaned. The length of the ejector 2 corresponds to the length of the mixing chamber according to the invention 5 up to the inlet in the flow channel 9 , so in cleaning position the ejector 2 the mixing chamber 5 completely cleans, but not in the filler channel 6 or the flow channel 9 enough. To get a good cleaning of filler channel 6 and flow channel 9 to allow, is the impact surface of the ejector 2 concave. In particular, it is provided with such a curvature, that of the cylindrical shape of the flow channel 9 equivalent.

During the mixing of the reactive components with each other or of the reactive mixture with the solid-gas mixture is also the ejector 8th in firing position. After firing end is in the HD procedure after the ejector 2 , in ND procedure after cleaning the mixing chamber 5 the ejector 8th brought into cleaning position, the ejector 8th at least as long as the filler chamber 6 and the flow channel 9 up to the outlet 7 ,

In a further embodiment of the device according to the invention, the ejector comprises 8th a sleeve 11 and a mobile core 10 , where the sleeve 11 in firing position at the level of the at least one inlet 1 has at least one opening through which the filler-gas mixture in the filler channel 6 is introduced and in the sense of the flow direction before the confluence of the mixing chamber 5 in the flow channel 9 ends, and the core 10 in the firing position in the direction of the flow direction above the at least one inlet 1 ends.

This way have mixing chamber 5 , Filler channel 6 and flow channel 9 from each other different inner diameter, wherein in particular the inner diameter of the filler channel 6 smaller than the inner diameter of the flow channel 9 , Will now over the at least one inlet 1 a filler-gas mixture in the filler channel 6 initiated, it comes at the bottom of the sleeve 11 to a turbulence of the filler-gas mixture due to the increase in the diameter. These turbulences improve the mixing of the filler (s) with that from the mixing chamber 5 flowing reactive mixture and thus to a uniform wetting of the / the fillers (s) with the reactive mixture. The resulting filler-containing reactive gas mixture leaves via an outlet opening 7 the flow channel 9 , According to the invention, the flow channel can also be used here 9 at least one, in particular several gas channels 3 which are on the same or different levels are located. Through the over the at least one gas channel 3 inflowing mixed gas, the filler-containing reactive gas mixture is further vortexed. At the outlet 7 Then, a mixture emerges in which the filler (s) is / are completely and uniformly wetted with the reactive mixture.

At the end of the shot become filler channel 6 and flow channel 9 through the ejector 8th comprising the sleeve 11 and the core 10 , mechanically cleaned. According to the invention leads to cleaning the sleeve 11 completely in the flow channel 9 at least to the outlet opening 7 a, so that the at least one opening of the sleeve 11 in the amount of at least one first gas channel in the flow direction 3 located. This allows the cleaning of the inside of the sleeve as well as the bottom surface of the core 10 with one of the at least one gas channel 3 in the sleeve 11 introduced gas stream. The core 10 is designed so that he, he is in cleaning position in the sleeve 11 inserted, with the bottom edge of the sleeve 11 completes flat.

In a further embodiment of the device according to the invention, the outlet opening tapers 7 in the flow direction.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 3909017 C1 [0007]
• DE 4010752 A1 [0007]
• DE 2517864 A1 [0013]
• US Pat. No. 3,328,291 A [0013]
• WO 2009/052990 A1 [0013]
• EP 1458494 B1 [0013]
• WO 2009/143979 A1 [0015]
• DE 102007016785 A1 [0016]
• DE 4417596 A1 [0016]
• EP 0771259 B1 [0017]

Claims (14)

Apparatus for producing a filler-containing resin spray comprising a. a cylindrical filler channel ( 6 ) with at least one inlet ( 1 ), for introducing a mixture of transport gas and filler, and an axially movable ejector therein ( 8th b. a cylindrical flow channel ( 9 ) for introducing filler from the filler channel ( 6 ) and c. a cylindrical mixing chamber ( 5 ) with at least two inlet openings ( 4 ) for the metered addition of at least two reactive components, wherein the mixing chamber ( 5 ) and the filler channel ( 6 ) include an angle which is not equal to 180 °, while the filler channel ( 6 ) and the flow channel ( 9 ) enclose an angle of 180 °. Device according to claim 1, characterized in that it further comprises an axially in the mixing chamber ( 5 ) movable ejector ( 2 ). Device according to claim 2, characterized in that the length of the ejector ( 2 ) the length of the mixing chamber ( 5 ) to the inlet in the flow channel ( 9 ) corresponds. Device according to one of claims 2 or 3, characterized in that the impact surface of the ejector ( 2 ) is concave, in particular provided with such a curvature, the cylindrical shape of the flow channel ( 9 ) corresponds. Device according to claim 1, characterized in that in the flow channel ( 9 ) at least one gas channel ( 3 ), preferably a plurality of gas channels ( 3 ) in at least one level. Device according to claim 5, characterized in that two gas channels ( 3 ) face each other on a plane. Device according to claim 5 or 6, characterized in that the at least one gas channel ( 3 ) is arranged so that the flow direction of the gas stream when entering the flow channel ( 9 ) outside the center of the flow channel ( 9 ) runs. Device according to claim 1, characterized in that the filler channel ( 6 ), Mixing chamber ( 5 ) and flow channel ( 9 ) have different inner diameters, wherein in particular the inner diameter of the filler channel ( 6 ) is smaller than the inner diameter of the flow channel ( 9 ). Device according to claim 1, characterized in that the ejector ( 8th ) is at least as long as the filler chamber ( 6 ) and the flow channel ( 9 ) to the outlet ( 7 ). Device according to claim 9, characterized in that the ejector ( 8th ) a sleeve ( 11 ) and a mobile core ( 10 ). Device according to claim 10, characterized in that the sleeve ( 11 ) in the firing position at least one opening at the level of the at least one inlet ( 1 ) and in the direction of the flow direction before the confluence of the mixing chamber ( 5 ) in the flow channel ( 9 ) ends. Apparatus according to claim 11, characterized in that the at least one opening of the sleeve ( 11 ) in the cleaning position in the amount of the at least one first gas channel in the flow direction ( 3 ) is located. Device according to one of claims 10 to 12, characterized in that the core ( 10 ) in the firing position in the direction of the flow direction above the at least one inlet ( 1 ) ends and in cleaning position so far in the flow channel ( 9 ) is located with the lower edge of the sleeve ( 11 ) completes flat. Device according to claim 1, characterized in that the outlet opening ( 7 ) tapers in the flow direction.

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